DE3935582A1 - BIO TEST DEVICE WITH LIGHT RADIATION - Google Patents

Description

The invention relates to a bio-experimental device for Experiment with living organisms that see exposed to light rays.

The applicant of the present patent application has recently suggested solar rays or artificial Rays of light by using lenses or the same focus and the bundled light radiate into an optical fiber cable from to which they are transferred to a place where the Light for lighting or for other purposes such as for cultivating plants, chlorella, fish or the like is needed. It turned out that the visible light, which is neither Ultra contains violet and infrared rays, not only promotes human health and aging prevents human skin from functioning of the body, but this light supports the healing of gout, neuralgia, sore localized areas, rheumatism, burn scars, skin diseases, broken bones, etc. and relieves the associated pain.  

On the basis of this knowledge, the applicant of the present patent application recently a Lichtbe radiation device for emitting visible light proposed without ultraviolet and infrared rays, to cure various diseases, beauty treatments perform actions and health too promote. This device irradiates the skin area of the Patients with the visible components of the spectrum sunlight or artificial light and transmits this through an optical fiber cable. The Device heals diseases with light, its infrared rays and ultraviolet rays are filtered out, that are known to be harmful. To the healing effect it is to increase the light irradiation of the device required, the amount of light, the wavelength of the com components to vary the light intensity etc. Except the combined effect of the medical Be action and the use of light irradiation of experimental animals such as rabbits, mice, etc. be searched.

The present invention is based on the object a bio-experimental device for experimenting with living Organisms indicate the visible rays of light be set. The device is said to be more effective Experi elements with living organisms in terms of effects allow exposure to visible light, whereby the radiation can be such that the energy intensity and / or color temperature changed or on fixed values can be maintained.  

This object is achieved by the im Characteristics of claim 1 specified Merk times solved. Advantageous developments of the invention are marked in the subclaims.

Further features, advantages and details of the invention emerge from the description below drafted embodiment and with reference to the drawing. Show:

Fig. 1 is a representation of the basic He clarification of the bio-ver testing device according to the invention;

Fig. 2 shows an embodiment of the bio-test device according to the invention with light irradiation;

Fig. 3 shows an embodiment of a sun rays collection and transmission device that can automatically collect sun rays and initiate into optical fiber cables that carry the rays to a desired location;

Fig. 4 is an illustration for explaining how the desired color component of the light is guided in an optical fiber cable and

Fig. 5 shows an example of a solar image which is focused by a lens.

Fig. 1 is an illustration explaining the operation of a bio-experimental device according to the invention. In Fig. 1, the reference numerals 1 a to 1 c denote optical fiber cables for transmitting sun rays or artificial light rays, which much of the red color component (for example, by the cable 1 a ), the blue color component (through the cable 1 b ) and the green Color component (through the cable 1 c ) included. The infrared and ultraviolet rays are filtered out because they are known to be harmful to living organisms. With 2 a movable plate is designated, which carries the optical fiber cables and is movable in the direction of the arrows A , while 3 denotes a transparent element that contains a transparent or hollow central portion 3 a and a peripheral portion 3 b , which preferably reflect de surface is formed to prevent the possibility of heat transfer to a subject who is exposed to light. 4 is a test container, 5 a subject (living organism), which is arranged in the test container 4 , and 6 denotes a base plate on which the test container 4 is arranged. The test container can be omitted if the subject 5 does not have to be arranged therein. Accordingly, the base plate 6 is not always required. 7 is a light energy sensor (illumination photometer), while 8 is a color temperature meter. The light energy sensor 7 determines the intensity of the light that is supplied to a living organism 7 so that the light irradiation energy can always be kept at an optimal level, while the color temperature meter 8 measures the color temperature of the light that is supplied to the living organism 5 , and that Wavelength components of the light so that the optimum color temperature of the light irradiation is always maintained. Since each living organism 5 requires its own optimal conditions with respect to the irradiation intensity and the color temperature of the light irradiation, in order to effectively carry out an experiment with a living organism, it is necessary to set the irradiation intensity and the color temperature of the light to the optimal values for the living organism . The radiation intensity (ie the light energy intensity) can be adjusted by moving the plate 2 in the direction of the arrows A in order to change the distance of the light-emitting ends of all optical fiber cables from the living organism. The color temperature of the light irradiation can be adjusted by individually shifting each light-emitting cable end in the direction indicated by the arrows B to change the distance of the living organism from the light-emitting end of the optical fiber cable, that is, the Change the intensity of the light that contains an abundance of a special color component.

Fig. 2 shows an embodiment of the bio-experimental device according to the Invention, with which the radiation intensity and the color temperature of the light irradiation are adjustable. In Fig. 2, 10 designate a holding plate (corresponding to the transparent plate 3 shown in FIG. 1), 11 columns which are arranged vertically on the holding plate 10 , 12 a fixed plate which is held by the upper ends of the columns 11 , 13 a movable plate which is vertically movable along the columns 11 (this movable plate corresponds to the movable plate 2 according to FIG. 1), 14 a motor for moving the plate 13 in the direction of the arrows A , 15 a feed spindle which is by the motor 14 is rotated, and 16 a nut which is in threaded engagement with the feed screw and is integrally attached to the plate 13 . When the feed screw 15 is rotated by the motor 14 , the nut 16 moves together with the movable plate 13 in the direction of the arrows A. 17 is the light-emitting end of an optical fiber cable which is fixed in the middle of the plate 13 , and 18 a , 18 b and 18 c ( 18 c is not shown) denote further optical fiber cable ends, each of which is attached to the cable in such a way Plate 13 are fixed so that they can be moved in the direction of arrows B and pivoted in the direction of arrows R. 19 a , 19 b and 19 c ( 19 c not shown) denote arms for holding the optical fiber cables 18 a , 18 b and 18 c . 20 a , 20 b and 20 c ( 20 c not shown) are arms for moving the holding arms 19 a , 19 b , 19 c in the direction of the arrows B and for pivoting the arms in the direction of the arrows R. 21 a , 21 b and 21 c ( 21 c not shown) are motors for pivoting associated pairs of arms 20 a , 19 a ; 20 b , 19 b ; and 20 c , 19 c in the direction of arrows R. 22 a , 22 b and 22 c ( 22 c not shown) are movement arms which are movable in the direction of the arrows C when they are driven by the associated motors 21 a , 21 b and 21 c . 23 a , 23 b and 23 c ( 23 c not shown) are motors for rotating feed spindles 24 a , 24 b and 24 c ( 24 b and 24 c are not formed). 25 a , 25 b and 25 c ( 25 b and 25 c are not shown) are nuts which are in threaded engagement with the associated feed spindles 24 a , 24 b and 24 c . The light that is sent from the optical fiber cable 17 arranged in the middle of the movable plate can, for example, correspond to the white sunlight. (As will be described later, the optical fiber cable 17 is not always required). The light that b out of the optical fiber cable 18 is sandt, contains plenty of the red color component, while the emitted light b from the optical fiber cable 18 contains a wealth of blue color component. The light emitted by the optical fiber cable 18 c contains an abundance of the green color component. Accordingly, the entire composite light can be varied in color, for example white, red, blue or green, by adjusting the amount of light rays of the cables 18 a , 18 b and 18 c accordingly. Since white light can be obtained by mixing the light rays from the optical fiber cables 18 a , 18 b and 18 c with one another, the optical fiber cable 17 is not always necessary. In the illustrated state of the illustrated embodiment, the light rays from the optical fiber cables 17 , 18 a , 18 b and 18 c each run through the transparent section 10 a of the holding plate 10 and are then mixed together in the vicinity of the subject 28 to form a together to set light to irradiate the subject. The radiation intensity and the color temperature of the composite light can be set to optimal values for the subject 28 . However, if the subject 28 is replaced by another or if one of the test conditions changes, the fixed values of the irradiation intensity of the composite light and the color temperature must be readjusted. Even if the same subject is exposed to light with constant radiation intensity and color temperature, a new setting may be necessary, since both parameters of the light transmitted through the optical fiber cables can change in one day and depending on the weather, the color of the sunlight in the morning and turns red in the evening.

In Fig. 2, the light energy intensity can be adjusted by moving the plate 13 in the direction of arrows B using the motor drive 14 . However, since the optical fiber cables 18 a , 18 b and 18 c are moved upwards or downwards together with the plate 13 , the location for forming the composite light shifts away from the subject to be irradiated if no additional adjustment is made if the movable plate 13 is adjusted. The motors 21 a , 21 b and 21 c and the movement arms 22 a , 22 b and 22 c can compensate for this cable shift. If the plate 13 is moved vertically by the motor 14 together with the optical fiber cables, the arms 22 a , 22 b and 22 c are moved simultaneously by the associated motors 21 a , 21 b and 21 c , so that they move in the direction arrows C. The movement of each arm is brought about by the interaction of a feed spindle and a fixed nut. A feed screw 21 a '( 21 b ', 21 c ') which is rotated by the motor 21 a ( 21 b , 21 c ), and a nut 22 a ( 22 b ', 22 c ') on the arm 22nd a ( 22 b , 22 c ) is fixed, are in engagement with each other. The arm 22 a can be moved by the motor 21 a via the feed mechanism mentioned above in the direction of the arrows C. For example, when the plate 13 is moved upward, the arm 22 a synchronism in the direction of the motor 21 a is pulled. When the plate 13 is moved downward, the arm 22 a is pushed away from the motor 21 a synchronously. Such movements of the arm 22 a ( 22 b , 22 c ) are accompanied by pivotal movements of the arms 24 a and 19 a ( 24 b and 19 b , 24 C and 19 c ) in the direction of the arrows R around the breakpoints 26 a , thereby the Beams of light from the optical fiber cables are directed toward the subject. In other words, the light rays can be focused on the subject without changing their color temperature. The setting of the color temperature of the light irradiation for the subject 28 can be carried out as follows:

When the feed screw 24 a ( 24 b , 24 c ) is rotated by the motor 23 a ( 23 b , 23 c ), the nut 25 a ( 25 b , 25 c ) moves, which is in threaded engagement with the feed screw 24 a stands and is attached to the plate, in the longitudinal direction of the feed screw 24 a , so that the arm 19 a , which holds the optical fiber cable 18 a , is moved in the direction of arrow B to adjust the color temperature of the light. The light color temperature can be set, for example, close to red by bringing the optical fiber cable 18 a , which transmits light with an abundance of the red color component, closer to the subject 28 , while at the same time the other optical fiber cables 18 b , 18 c from the subject 28 further apart.

Thus, any desired color temperature of the light can be obtained by adjusting the distance of the subject 28 from the light-emitting ends of the optical fiber cables 18 a to 18 c . Adjustment devices 27 are provided for adjusting the height of the holding plate 10 so that the subject arranged under the holding plate 10 can be suitably exposed to the light rays. In the case of Fig. 2, the subject exposed to light irradiation is an animal, other types of living subjects such as humans, plants, fish, cells, etc. can also be exposed to the radiation. For example, an experiment can be carried out with a subject placed in a test container (see FIG. 1) under the holding plate 10 .

Fig. 3 explains an example of a solar radiation collector device for guiding the sun light in the aforementioned optical fiber cable. As shown in FIG. 3, the solar radiation collector device contains a transparent protective capsule 30 , Fresnel lenses 31 , lens holders 32 , a sun position sensor 33 , optical fiber cables, which are composed of a large number of optical fibers 34 , optical cable holders 35 , an arm 36 , one pulse motor 37, a horizontal rotary shaft 38 which is driven by the pulse motor or stepping motor 37, a base 39 for supporting the protective capsule 30, a pulse motor 40 and a vertical rotation shaft 41, the 40 is driven motor of the pulse.

The direction of the sun is detected by means of the sun position sensor 33 , and its detection signal controls the pulse motors 37 and 40 to rotate the horizontal shaft 38 and the vertical shaft 41 so that the lenses 31 are always directed towards the sun. The sunlight, which is bundled by each lens 31 , is guided in each optical fiber 34 through the end face, which is arranged at the focal point of the lens. The optical fibers 34 , which are arranged on the respective lenses 31 , are combined and bundled as a cable 1 , which is guided by the solar radiation collector device to any desired location where the light rays are used to bio-ver search to To investigate the effect of light on living organisms.

Figure 4 explains how the sun's rays are directed into an optical fiber. In Fig. 4, 31 designates a Fresnel lens or the like and 34 an optical fiber which receives the sun rays bundled by the lens 31 and transmits them to a desired place where the light is needed. When the sunlight is focused by the lens system, the sun image, as shown in FIG. 5, has a central portion A which is composed almost entirely of white light and a peripheral portion B which contains a large amount of light components with wavelengths that are the focus of the Lens system. When sunlight is focused through the lens system, the focal point and size of the sun image vary depending on the wavelengths of the component of the light. The blue light, for example, which has a short wavelength, causes a sun image with a diameter D 1 at a point P 1 . The green light produces a sun image with a diameter D 2 at a point P 2 , while the red light produces a sun image with a diameter D 3 at a point P 3 . Accordingly, as shown in Fig. 4, when the light receiving end face of the optical fiber is placed at the position P 1 , it is possible to collect sunlight which contains a large portion of the blue color component at the peripheral portion. If the light-receiving end face of the optical fiber is arranged at the position P 2 , it is possible to collect sunlight which contains much of the green color component at the peripheral portion. Placing the light receiving end face of the optical fiber at the position P 3 enables sunlight to be collected which contains a large amount of the red color component at its peripheral portion. In any case, the diameter of the optical fiber can be selected according to the light components to be collected. For example, the required diameter of the optical fiber cables D 1 , D 2 and D 3 , depending on the colors of the light rays, to which value is placed, ie the blue, green or red color. In this way, the required size of the optical fiber cable can be determined, and sunlight with an abundance of the desired color components can be collected extremely effectively. In addition, as shown in Fig. 4, if the diameter of the light receiving end surface of the optical fiber cable is increased to D 0 , it is possible to collect visible light containing all the wavelength components.

The optical fibers can be light-on taking ends at the associated focal points of the respective lenses in the solar radiation collector device to be attached during manufacture, or they can be movable in the solar radiation collector be attached so that the positions of their Light-receiving ends additionally by the user can be adjusted in the axial direction of the lenses can, depending on the colors of the light to be collected.

From the above description it follows that the bio-experimental device according to the invention is irradiated of a living subject with visible light, where the energy intensity and / or the color tempera structure changed or kept at fixed values can be, which makes precise and effective Experi ment with living subjects regarding their react tion can be carried out on light.

Claims (4)

1. Bio-experimental device with a base plate with a transparent section, supports that are mounted vertically on the base plate, a movable plate that is movably attached to the vertical supports, and cables with at least three optical fibers that are pivotable on the movable Plate be fastened, characterized in that to carry out an experiment on a under the transparent portion ( 10 a ) of the base plate ( 10 ) arranged subject ( 28 ), which is irradiated with light rays from the light-emitting ends of the optical fiber cables ( 18 a , 18 b , 18 c ), one of the three optical fiber cables emits light that contains an abundance of the red component of the color spectrum, another cable emits light that contains an abundance of the blue component, and the rest Cable emits light rays that contain an abundance of the green component of the color spectrum, and that each optical fiber Abel is provided with a device that adjusts the inclination angle ( R ) of the optical fiber cable simultaneously with the vertical movement of the plate ( 13 ) in such a way that the emitted light beams are always directed to the transparent portion 10 a of the base plate 10 . 2. Bio-experimental device according to claim 1, characterized by means for separately setting the light-emitting ends of each optical fiber cable ( 18 a , 18 b , 18 c ) with respect to the transparent section ( 10 a ) of the base plate ( 10 ) in front of each set angle of inclination ( R ) of the respective cable. 3. Bio-experimental device according to claim 2 or 3, characterized in that a further optical fiber cable is arranged to transmit white light and to radiate through the transparent portion ( 10 a ) of the base plate ( 10 ) on the subject ( 28 ) . 4. Bio-experimental device according to claim 1 or 2, characterized in that on the base plate ( 10 ) an illumination intensity sensor and / or a color temperature sensor are attached / is to the vertical movement of the movable plate ( 13 ) according to the output signal of the illumination intensity sensor Control and / or adjust the distance of the transparent section ( 10 a ) of the base plate ( 10 ) from the light-emitting ends of all optical fiber cables ( 18 a , 18 b , 18 c ) according to a signal from the color temperature sensor.